KR101900097B1 - Image capturing method and image capturing apparatus - Google Patents

Abstract

The present invention relates to an image capturing method and an image capturing apparatus, which are capable of capturing an image at a high shutter speed by reducing an increase in an ISO value as much as possible and a shutter speed value as low as possible when an image is captured under low brightness conditions, It is an object of the present invention to obtain a single image with improved brightness by acquiring a plurality of images through a continuous shot in order to perform gamma correction for each of a plurality of images. To this end, an image capturing method according to the present invention includes: measuring an object in response to a first control signal; setting an ISO value and a shutter speed value in consideration of a result of photometry; Capturing a plurality of images in response to a second control signal by increasing an ISO value by a first magnitude and a shutter speed value by a second magnitude greater than a first magnitude; Performing gamma correction so that brightness increases for each of the plurality of images; A plurality of images subjected to gamma correction are synthesized to obtain a single image with improved brightness.

Description

[0001] IMAGE CAPTURING METHOD AND IMAGE CAPTURING APPARATUS [0002]

The present invention relates to an image capturing apparatus, and an image capturing apparatus and method for capturing an image of a subject.

An image capture device such as a digital camera and a camcorder has a scene mode in which an image capture mode is automatically set according to the state of the subject or surrounding environment, and an image is captured according to the set image capture mode. In this case, an image processing algorithm for each scene mode is provided in advance in the image capturing device, and when one scene mode is set, the image is processed according to an algorithm corresponding to the scene mode. For example, in the portrait mode, the face recognition function recognizes the face of the subject and captures the image when smiling. In the sports mode, the shutter speed is increased to accurately capture the moving subject image.

In capturing an image, the amount of light around the subject can be an important factor in determining the quality of the image. In other words, when the light amount is insufficient, the brightness of the image is not sufficient, so it may be difficult to distinguish the subject. Therefore, an appropriate amount of light must be secured according to the contents to be expressed through the image. However, depending on the situation around the subject, it may be difficult to obtain a sufficient amount of light. In such a case, the brightness of the image can not be obtained as much as desired due to the insufficient amount of light.

For this purpose, in the digital image capturing apparatus, the ISO value indicating the sensitivity of the image pickup element is raised to compensate for the insufficient amount of light. However, if you increase the ISO value too much, the quality of the image will deteriorate as the amount of noise appearing in the image increases as the brightness increases. Even if you want to increase the amount of light by increasing the shutter speed value (that is, by slowing down the shutter speed), the slow shutter speed causes the shake of the image capturing device to be reflected in the image, resulting in a shaken image.

According to one aspect, when capturing an image under low brightness conditions, it is desirable to reduce the increase in ISO value whenever possible and the shutter speed value to be as low as possible so that the image can be captured at a fast shutter speed, And acquires a plurality of images through gamma correction for each of a plurality of images, thereby obtaining a single image with improved brightness.

The image capturing method according to the present invention includes the steps of: performing photometry on an object in response to a first control signal, setting an ISO value and a shutter speed value in consideration of a result of photometry; Capturing a plurality of images in response to a second control signal by increasing an ISO value by a first magnitude and a shutter speed value by a second magnitude greater than a first magnitude; Performing gamma correction so that brightness increases for each of the plurality of images; A plurality of images subjected to gamma correction are synthesized to obtain a single image with improved brightness.

In addition, in the above-described image capturing method, a plurality of images are acquired through continuous shooting.

Further, in the image capture method described above, a plurality of images is an image in a low file format.

Further, in the image capturing method described above, each of the plurality of images in the low file format is converted into a reason v (YUV) file format in which brightness information and color information are expressed separately; And a plurality of images of the reason V file format are synthesized to obtain a single image.

Further, in the above-described image capturing method, the first control signal is the photometric control signal and the second control signal is the image capturing control signal.

Further, in the above-described image capturing method, an increase amount of the ISO value is determined so as to compensate for the shortage of exposure due to the decrease of the shutter speed value through the increase of the ISO value and the gamma correction.

In addition, in the image capturing method described above, when the shutter speed value is reduced by n stops, the OS value is increased by n / 2 stops, and the brightness corresponding to n / 2 stops of the OS value is compensated through gamma correction.

Further, in the image capturing method described above, the method further includes compositing the plurality of images to obtain a single image, and then deleting the plurality of images.

Another image capturing method according to the present invention is characterized in that the image capturing device is set to a low brightness capture mode; Performing photometry on the subject in response to the first control signal, setting an ISO value and a shutter speed value in consideration of the photometry result; Capturing a plurality of images in response to a second control signal by increasing an ISO value by a first magnitude and a shutter speed value by a second magnitude greater than a first magnitude; Performing gamma correction so that brightness increases for each of the plurality of images; A plurality of images subjected to gamma correction are synthesized to obtain a single image having improved brightness.

Further, in the image capturing method described above, the low brightness capture mode is automatically set to the low brightness capture mode.

Further, in the above-described image capturing method, the low-brightness capture mode is automatically set to the low-brightness capture mode; The low luminance capture mode is performed through the display unit when the low luminance capture mode is performed.

Further, in the above-described image capturing method, the image capturing apparatus is forced to the low-luminance capturing mode by the setting of the user.

An image capturing apparatus according to the present invention includes: an image sensing element whose sensitivity is determined by an ISO value;

A shutter whose speed is determined by a shutter speed value; A digital signal processor for performing gamma correction of the acquired image; And the shutter speed value is set in consideration of the result of the photometry. In response to the second control signal, the shutter speed value is increased by the first magnitude in response to the first control signal, Capturing a plurality of images by reducing a second size larger than the first size, performing gamma correction so that brightness increases for each of the plurality of images, synthesizing a plurality of images subjected to the gamma correction, And controls to acquire an image.

In addition, in the image capturing apparatus described above, the control unit determines an increase amount of the ISO value so as to compensate for the lack of exposure due to the decrease of the shutter speed value through the increase of the ISO value and the gamma correction.

In addition, in the image capturing apparatus described above, the control unit increases the value of the OSu by n / 2 stops when the shutter speed value decreases n stops, and compensates the brightness corresponding to n / 2 stops of the OSu value through gamma correction.

According to one aspect, when capturing an image under low brightness conditions, it is desirable to reduce the increase in ISO value whenever possible and the shutter speed value to be as low as possible so that the image can be captured at a fast shutter speed, And combining them by performing a gamma correction on each of the plurality of images, a clear image due to low noise due to a low ISO value and a sharp shutter speed, a high quality image compensated for insufficient brightness due to gamma correction Can be obtained.

1 is a block diagram of an image capture apparatus according to an embodiment of the present invention.
Fig. 2 is a diagram showing a control system of the image capturing apparatus shown in Fig. 1. Fig.
3 is a diagram showing a first embodiment of a digital signal processing unit of the image capture apparatus shown in FIG.
4 is a flowchart illustrating an image capture control method according to an embodiment of the present invention.
5 is a flowchart illustrating an image capture control method according to another embodiment of the present invention.
6 is a diagram showing a second embodiment of the digital signal processing unit of the image capture apparatus shown in FIG.
7 is a flowchart illustrating an image capture control method according to an embodiment of the present invention.
8 is a diagram illustrating a method of capturing an image in a low-brightness capture mode according to an embodiment of the present invention.

1 is a block diagram of an image capture apparatus according to an embodiment of the present invention. 1 shows a digital camera which captures an image of a subject and converts it into digital data and records it in a storage device, as an example of the image capturing device 150. Of course, the present invention is not limited to the digital camera shown in FIG. 1, and the present invention can be applied to an image capturing apparatus such as a camcorder and a mobile communication terminal (a camera is equipped). In addition, the present invention can be applied to a case where a television, a computer, or the like is connected to be capable of communicating with an image capturing apparatus through wired / wireless communication means. Here, the image may be a still image or a moving image. The capture of an image is the task of storing the image of the subject in a data format. In the image capture device 150 of Figure 1, the display portion 152 may display an image of the subject input through the lens before the image is captured, and may display the captured image after the image is captured . Further, while the image of the subject is being displayed or the captured image is being displayed, a user interface for setting various options and menus and information related to image capturing together with each image may be displayed.

Fig. 2 is a diagram showing a control system of the image capturing apparatus shown in Fig. 1. Fig. The overall operation of the image capturing apparatus 150 is controlled by the control unit 100. [ The image capturing apparatus 150 includes an operation unit 200 that generates a predetermined electrical signal in response to a user's operation and transmits the electrical signal to the control unit 100 so that the intention of the user is transmitted to the control unit 100. The electrical signal from the operation unit 200 is transmitted to the control unit 100 so that the control unit 100 can control the image capture device 150 according to the electrical signal. The operation unit 200 is separate from the user interface provided in the display unit 152. Unlike the user interface provided in the display unit 152 is a software based graphical user interface, Is for hardware-based mechanical manipulation. The elements constituting the operation unit 200 include, for example, an arrow key, a command dial, a wheel, and various other types of buttons.

The control unit 100 controls the lens driving unit 11, the diaphragm driving unit 21, the shutter driving unit 91 and the imaging device driving unit 31 to capture an image, and accordingly controls the position of the lens 10, the diaphragm 20 The release of the shutter 90, the sensitivity of the image pickup device 30, and the like are controlled. The image pickup device 30 converts the inputted optical signal into an analog electric signal, which is converted into digital data by the analog / digital conversion unit 40. [ Alternatively, the image pickup device 30 itself may perform the digital conversion without the separate analog-to-digital conversion unit 40 being present. In the case of an electronic shutter that does not have a separate physical shutter 90 and instead implements a shutter function through electronic control of the image pickup element 30, the image pickup element 30 is controlled by the control unit 100, Can be implemented.

The image data generated by the image pickup element 30 and passed through the analog / digital conversion section 40 can be input to the digital signal processing section 50 via the memory 60, Or may be directly input to the control unit 100 as needed. Here, the memory 60 includes a ROM (Read Only Memory) or a RAM (Random Access Memory). The digital signal processing unit 50 may perform digital signal processing such as gamma correction, white balance change, and the like as necessary.

The image data output from the digital signal processing unit 50 is transmitted to the display unit 152 and displayed as an image. In the image capturing apparatus 150 according to the exemplary embodiment of the present invention, the display unit 152 may be a touch screen type, and a predetermined input operation may be performed by touching the display unit 152. [ The image data output from the digital signal processing unit 50 is input to the memory 60 or directly to the storage / read control unit 71. The storage / And stores the image data in the storage medium 70 as an image file in accordance with the storage routine. Of course, the storage / read control unit 71 reads the data from the image file stored in the storage medium 70 and provides it to the display unit 152 through the memory 60 or another path so that the image is displayed You may. The storage medium 70 may be removable through the memory slot or may be fixedly attached to the image capture device 150.

3 is a diagram showing a first embodiment of a digital signal processing unit of the image capture apparatus shown in FIG. In particular, the first embodiment of the digital signal processing unit 50 shown in FIG. 3 is similar to the first embodiment of the digital signal processing unit 50 in that the image capture device 150 itself in the low-brightness capture mode according to the embodiment of the present invention, For example, a low brightness condition, and so on, so as to select the entry into the low brightness capture mode. At this time, the user does not participate in the selection of the low-luminance capture mode. The low brightness capture mode according to the embodiment of the present invention is a mode in which the sensitivity of the image sensing device 30 (ISO (ISO)) in the process of capturing and synthesizing a plurality of images, in order to obtain an image with sufficient brightness even under low- (ISO value) of the image pickup element 30 is minimized within a permissible range and the shutter speed value SS is made the fastest within the permissible range, in order to compensate for the decrease in brightness caused by minimizing the sensitivity Gamma correction is performed on each of the plurality of images to secure a brightness of a certain level or higher. The determination of the low brightness condition can be made based on the amount of light received through the lens 10 or based on the amount of light around the image capturing device 150 measured using a separate illuminance sensor have. In this case, the reference light amount may be set in advance, and the low brightness capture mode according to the embodiment of the present invention may be executed when the measured actual light amount is equal to or less than the reference light amount. Alternatively, the brightness information may be obtained through histogram analysis of the preview image, and the execution of the low brightness capture mode may be determined based on the brightness information of the preview image.

To this end, the digital signal processing unit 50 shown in FIG. 3 includes a low-luminance capture mode selection unit 51. FIG. The low brightness capture mode selection unit 51 allows the image capture device 150 to enter the low brightness capture mode when the amount of light around the image capture device 150 is equal to or less than a preset reference light amount.

4 is a flowchart illustrating an image capture control method according to an embodiment of the present invention. In the image capturing control method shown in Fig. 4, a low luminance capture mode is selected according to the determination of the digital signal processing unit 50, and a low luminance capture mode is performed under the control of the control unit 100. [

As shown in FIG. 4, when the image capturing apparatus 150 is powered on, the control unit 100 receives the setting of the basic operation condition (402). The setting of the basic operation condition includes setting the basic operation condition of the image capture such as the setting of the operation mode and the setting of the image size quality (resolution). In this state, when the S1 signal (first control signal) is generated, the control unit 100 performs focusing and photometry on the subject, and sets a first image capturing condition considering the photometric information (406). The S1 signal is a signal generated in order to cause focusing and photometry to be performed on the subject during the primary operation of the shutter release button 158 by the user. At this point, the image is not captured. The first image capturing condition set in response to the S1 signal generation includes an ISO value and a shutter speed value SS, which are the sensitivity of the image pickup device 30 in consideration of meteorological information. For example, considering the photometric information around the image capturing apparatus 150, the ISO value, which is a main condition for determining the brightness of the image, can be set to 100, and the shutter speed value can be set to 1 s (second, second). Of course, the ISO value and the shutter speed value may vary depending on the photometric information around the image capturing apparatus 150. [ When a first image capturing condition including an ISO value and a shutter speed value is set, a preview image reflecting the set first image capturing condition is generated and displayed through the display unit 152 (408). In the display step of the preview image, if it is determined that the amount of light around the image capturing apparatus 150 is insufficient and the brightness is low (YES in step 410), the control unit 100 controls the image capturing apparatus 150 to the low brightness capture mode (412). If the user further operates the shutter release button 158 to generate the S2 signal (second control signal), which is the image capture signal, after the operation mode of the image capture device 150 is switched to the low-brightness capture mode ), Captures an image in a low-intensity capture mode and stores it in storage medium 70 (416). The S2 signal is a signal that is generated to cause the image to be captured in response to an additional operation of the shutter release button 158 after the generation of the S1 signal. Image capturing and storage in the low-intensity capture mode will be described in detail in FIG. 8 to be described later. If the low brightness condition is not the low brightness condition (No in 410), in the low brightness condition determination step 410, in the image capture mode other than the low brightness capture mode (for example, the image capture mode according to the basic condition set in step 402) Performs image capture, and stores the captured image on the storage medium 70 (418). Of course, even when capturing an image in normal image capture mode, an image is captured in response to the occurrence of the S2 signal.

5 is a flowchart illustrating an image capture control method according to another embodiment of the present invention. In the image capturing control method shown in Fig. 5, the low brightness capture mode is selected according to the determination of the digital signal processing unit 50, and the low brightness capture mode is performed under the control of the control unit 100. [ However, when switching to the low-brightness capture mode, the display unit 152 displays a guide message informing the user that the low-brightness capture mode is switched, thereby informing the user that the operation mode of the image capture device 150 is switched to the low- .

As shown in FIG. 5, when the image capturing apparatus 150 is powered on, the control unit 100 receives the setting of the basic operation condition (502). The setting of the basic operation condition includes setting the basic operation condition of the image capture such as the setting of the operation mode and the setting of the image size quality (resolution). When the S1 signal (first control signal) is generated in this state, the controller 100 sets a first image capturing condition considering the surrounding environment of the image capturing apparatus 150 (506). The S1 signal is a signal generated in order to cause focusing and photometry to be performed on the subject during the primary operation of the shutter release button 158 by the user. At this point, the image is not captured. The first image capturing condition set when the S1 signal is generated includes the ISO value, which is the sensitivity of the image pickup device 30, and the shutter speed value SS. For example, considering the amount of light around the image capturing apparatus 150, the ISO value, which is a main condition for determining the brightness of the image, can be set to 100, and the shutter speed value can be set to 1 s (second, second). Of course, the ISO value and the shutter speed value may vary depending on the amount of light around the image capturing apparatus 150. [ When a first image capturing condition including an ISO value and a shutter speed value is set, a preview image reflecting the set first image capturing condition is generated and displayed on the display unit 152 (508). The control unit 100 determines that the operation mode of the image capturing apparatus 150 is a low brightness condition (YES in step 510) Display a guidance message to guide the user to switch to the low-brightness capture mode through the display unit 152 to inform the user that the capture mode is switched to the capture mode, and display an operation mode of the image capture device 150 for performing the low- (512). The user recognizes that the image capturing apparatus 150 is switched to the low brightness capture mode through the guidance message displayed on the display unit 152 and when the low brightness capture mode is to be continuously performed, And conversely, if it is not desired to perform the low brightness capture mode, the S1 state (i.e., the focus state) of the shutter release button 158 may be canceled so that the image capture in the low brightness capture mode is not performed. The S2 signal is a signal that is generated to cause the image to be captured in response to an additional operation of the shutter release button 158 after the generation of the S1 signal. When the user operates the shutter release button 158 additionally after the operation mode of the image capturing device 150 is switched to the low brightness capture mode and an S2 capturing signal (second control signal) is generated ), Captures the image in low-intensity capture mode and stores it in storage medium 70 (516). Image capturing and storage in the low-intensity capture mode will be described in detail in FIG. 8 to be described later. If the low brightness condition is not the low brightness condition (No in 510), in the low brightness condition determination step 510, in the image capture mode other than the low brightness capture mode (for example, the image capture mode according to the basic condition set in step 402) Performs image capture, and stores the captured image on the storage medium 70 (518). Of course, even when capturing an image in normal image capture mode, an image is captured in response to the occurrence of the S2 signal.

6 is a diagram showing a second embodiment of the digital signal processing unit of the image capture apparatus shown in FIG. Particularly, the second embodiment of the digital signal processing unit 50 shown in Fig. 6 is for allowing the user to directly select the low brightness capture mode. The user determines whether to set the low brightness capture mode by determining the amount of light at the place where the user is located. If it is determined that the setting to the low brightness capture mode is necessary, a separate dial or the like provided in the operation unit 200 is rotated, You can set the capture mode.

To this end, the digital signal processing unit 50 shown in Fig. 6 includes a low brightness capture mode selection receiving unit 52. [ The low brightness capture mode selection receiving unit 52 receives the low brightness capture mode selection signal generated when the user selects the low brightness capture mode through the operation unit 200 and notifies the digital signal processing unit 50 of the low brightness capture mode, So that the digital signal processor 50 can know that the capture mode has been selected.

7 is a flowchart illustrating an image capture control method according to an embodiment of the present invention. 7, the operation mode of the image capturing apparatus 150 is forcibly set to the low-brightness capture mode by the user's selection, and the low-brightness capture mode is performed under the control of the control unit 100. [

As shown in FIG. 7, when the image capturing apparatus 150 is powered on, the control unit 100 receives the setting of the basic operation condition (702). The setting of the basic operation condition includes setting the basic operation condition of the image capture such as the setting of the operation mode and the setting of the image size quality (resolution). In addition, it also includes the user forcing the operation mode of the image capture device 150 to the low brightness capture mode. When the S1 signal (first control signal) is generated in this state, the controller 100 sets a first image capturing condition considering the surrounding environment of the image capturing apparatus 150 (706). The S1 signal is a signal generated in order to cause focusing and photometry to be performed on the subject during the primary operation of the shutter release button 158 by the user. At this point, the image is not captured. The first image capturing condition set when the S1 signal is generated includes the ISO value, which is the sensitivity of the image pickup device 30, and the shutter speed value SS. For example, considering the amount of light around the image capturing apparatus 150, the ISO value, which is a main condition for determining the brightness of the image, can be set to 100, and the shutter speed value can be set to 1 s (second, second). Of course, the ISO value and the shutter speed value may vary depending on the amount of light around the image capturing apparatus 150. [ When a first image capturing condition including an ISO value and a shutter speed value is set, a preview image reflecting the set first image capturing condition is generated and displayed through the display unit 152 (708). When the user further operates the shutter release button 158 in a state in which the preview image is being displayed to generate an S2 signal (second control signal) as an image capture signal (for example), the image is captured in the low- (710). The S2 signal is a signal that is generated to cause the image to be captured in response to an additional operation of the shutter release button 158 after the generation of the S1 signal. Image capturing and storage in the low-intensity capture mode will be described in detail in FIG. 8 to be described later.

8 is a diagram illustrating a method of capturing an image in a low-brightness capture mode according to an embodiment of the present invention. That is, the image capture method shown in FIG. 8 includes steps of image capture and storage 416 in the low brightness capture mode of FIG. 4 and image capture and storage 516 in the low brightness capture mode of FIG. And the image capturing and storing step 712 in the low brightness capture mode.

8, in order to capture an image in the low brightness capture mode, the control unit 100 sets the ISO value of the first image capturing condition and the shutter speed value SS (802). Then, in order to overcome the low brightness condition, the ISO value of the first image capturing condition is increased, and the second image capturing condition is selected in which the increase value is made as small as possible and the shutter speed value is decreased, (804). For example, in order to overcome the low brightness condition around the image capturing apparatus 150, when the ISO value set at the time S1 is increased by two stops, for example, from 100 to 400, in the low brightness capture mode of the present invention Increase the ISO value from 100 to 200 by one stop. The increase of the ISO value increases the sensitivity of the image pickup device 30 so that a brighter image can be realized even in a low brightness condition, but an increase in the ISO value causes more noise in the image. Therefore, in order to obtain a high-quality image with low noise, it is desirable to lower the ISO value as much as possible. Therefore, in the low brightness capture mode according to the embodiment of the present invention, the degree of increase of the ISO value is minimized as much as possible. Since it is desirable to reduce the shutter speed value to a small value if possible in order to minimize the shake even under low brightness conditions, the shutter speed value set at the time S1 is decreased by two stops, for example, from 1s to 1 / 4s. Here, the decrease in the shutter speed value means that the numerical value (1 / 4s, 1 / 8s, etc.) indicating the shutter speed is reduced, which means that the shutter speed is released at a faster speed. As the release speed of the shutter becomes faster, the time for which the image pickup device 30 is exposed to light is shortened, so that it is less affected by the shaking of the image capturing device 150, and a clearer image can be obtained. The correlation between the ISO value and the shutter speed value in the low brightness capture mode according to the embodiment of the present invention is such that when the shutter speed value decreases by n stops, the OS value increases by n / 2 stops and the value of n / It can be summarized as compensating the corresponding brightness through gamma correction.

In step 804, a plurality of images are captured through the burst while the ISO value is increased by one stop and the shutter speed value is decreased by two stops, and the captured images are temporarily stored in the memory 60 (806) . At this time, the plurality of images obtained by the speaker are an image of a Raw File Format in which no special conversion is performed, and the image of this low file format is converted into the YUV format and subjected to gamma correction. The YUV format separates the brightness information (Y) and color information (UV) of the image. If the shutter speed value decreases, the amount of light incident on the image sensing element 30 also decreases. Therefore, the ISO value must also be increased to two levels. In the low-luminance capture mode according to the embodiment of the present invention, To reduce the ISO value by one stop rather than by two stops to minimize as much as possible, and instead to compensate for the poor exposure of the image, a predetermined format (e.g., JPEG or TIFF) for each of the low- Format) and gamma correction is performed on each continuous image (808). The gamma correction adjusts the brightness of each of the plurality of continuous images by correcting the input brightness component (Yin) of the continuous image for each of the plurality of continuous images to correct the output brightness component (Yout). The low brightness capture mode according to the embodiment of the present invention is intended to improve the brightness of the final image by increasing the brightness of each of the plurality of continuous images and compositing them.

When gamma correction is completed for each of the plurality of images obtained by the continuous shooting, a plurality of gamma-corrected images are synthesized into one image to generate a final image, and the generated final image is stored in the storage device 70 ). This allows a minimum level of ISO value and gamma correction to achieve a certain level of brightness with less noise, and by reducing the shutter speed value, it is possible to combine multiple images with minimal shake even under low brightness conditions, It is possible to obtain a final image that satisfies all of the above brightness and sharpness of image quality. When the storage of the final image is completed, the images of the low file format and the YUV file format stored in the memory 60 are deleted to secure the storage space of the memory 60 (812). Optionally, the user may provide both the continuous images of the low file format and the final image to the user by storing the continuous images in the low file format in the storage medium 70 together with the final image without deleting them.

10: Lens
11:
20: aperture
21:
30:
31: Imaging element driving part
40: analog / digital conversion section
50: Digital signal processor
51: low brightness capture mode selection unit
52: low brightness capture mode selection receiver
60: Memory
70: Storage medium
71: Storage /
90: Shutter
91:
100:
152:
200:

Claims (15)

Performing photometry on the subject in response to the first control signal;
Determining whether the illuminance resulting from the photometry result falls within a preset range;
Setting an ISO value and a shutter speed value in consideration of the photometry result if the illuminance resulting from the photometry result is out of the predetermined range;
Capturing a plurality of images in response to a second control signal by increasing the eye-sight value by a first magnitude and decreasing the shutter speed value by a second magnitude greater than the first magnitude;
Performing gamma correction so that brightness increases for each of the plurality of images;
And combining the plurality of images subjected to the gamma correction to obtain a single brightness-improved image. The method according to claim 1,
And acquiring the plurality of images through a speaker. 3. The method of claim 2,
Wherein the plurality of images is an image in a low file format. The method of claim 3,
Converting each of the plurality of images in the low file format into a reason v (YUV) file format in which brightness information and color information are expressed separately;
And combining the plurality of images of the reason and the reason V file format to obtain the single image. The method according to claim 1,
Wherein the first control signal is a metering control signal and the second control signal is an image capture control signal. The method according to claim 1,
And determining an increase amount of the OSeso value so as to compensate for the lack of exposure due to the decrease of the shutter speed value through the increase of the OSeso value and the gamma correction. The method according to claim 6,
Wherein said step of increasing said shutter speed value by n / 2 stops when said shutter speed value decreases by n stops, and compensating for brightness corresponding to n / 2 stops of said shutter speed value by said gamma correction. The method according to claim 1,
And combining the plurality of images to obtain the single image and then deleting the plurality of images. The image capture device is set to low brightness capture mode;
Performing photometry on the subject in response to the first control signal;
Determining whether the illuminance resulting from the photometry result falls within a preset range;
Setting an ISO value and a shutter speed value in consideration of the photometry result if the illuminance resulting from the photometry result is out of the predetermined range;
Capturing a plurality of images in response to a second control signal by increasing the eye-sight value by a first magnitude and decreasing the shutter speed value by a second magnitude greater than the first magnitude;
Performing gamma correction so that brightness increases for each of the plurality of images;
And combining the plurality of gamma corrected images to obtain a single enhanced brightness image. 10. The method of claim 9,
Wherein the low brightness capture mode is automatically set to the low brightness capture mode when the low brightness condition is satisfied. 10. The method of claim 9,
The low brightness capture mode is automatically set to the low brightness capture mode;
Wherein the low brightness capture mode is performed through the display unit when the low brightness capture mode is performed. 10. The method of claim 9,
Wherein the image capturing device is forced to the low brightness capture mode by a setting of the user. An imaging element whose sensitivity is determined by an ISO value;
A shutter whose speed is determined by a shutter speed value;
A digital signal processor for performing gamma correction of the acquired image;
Wherein the control unit is configured to perform metering for the subject in response to the first control signal, determine whether the illuminance according to the result of the metering is within a predetermined range, and if the illuminance resulting from the metering result is out of the preset range, The shutter speed value is increased by a first magnitude in response to a second control signal and the shutter speed value is decreased by a second magnitude greater than the first magnification by setting a plurality of Capturing an image, performing gamma correction so as to increase the brightness for each of the plurality of images, and controlling the gamma correction to combine the plurality of images to obtain a single brightness-improved image Image capture device. 14. The apparatus of claim 13,
And determines an increase amount of the OSeso value so as to compensate for the lack of exposure as the shutter speed value is decreased through the increase of the OSeso value and the gamma correction. 15. The apparatus of claim 14,
And increases the value of n / 2 by n / 2 stops when the shutter speed value decreases by n stops, and compensates the brightness corresponding to n / 2 stops of the ieso value through the gamma correction.

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